1. New Results From CMS Y.Onel University of Iowa A Topical Conference on elementary particles, astrophysics and cosmology Miami 2011, Dec 15-20, 2011 conference on topical conference

2. CMS Collaboration 2

3. 3

4. LHC/CMS Operations in 2011 pp 7TeV 4

5. CMS Performance 5

6. Dimuon triggers at 10 32 -> 10 33 at CMS 6

7. Low Mass Resonances PDG Mass: 1321.71 ± 0.07 Ξ - → Λπ - PDG Mass: 1672.4 ± 0.3 Ω - → ΛK - 7

8. Inclusive Jet Cross-Sections 8

9. Excellent Understanding of the Physics Objects 9

10. Bose-Einstein Correlations 10

11. Angular Correlation Functions 11

12. Long-range near-side correlations in high multiplicity events (N>110) 12

13. Electroweak Bosons and Dibosons 13

14. Electroweak Bosons and Dibosons 14

15. Inclusive W Production 15

16. Inclusive Z Production 16

17. W → μν candidate 17

18. W → eν candidate 18

19. W → μν, W → eν 19

20. 20

21. 21

22. W/Z + Jets 22

23. W/Z + b/c Jets 23

24. 24

25. Top Pair Cross-Section 25

26. Top Pair Cross-Section 26

27. Top Physics Forward – Backward asymmetry CDF A FB tt = 0.158 ± 0.075 NLO A FB tt = 0.058 ± 0.009 LHC can see large BSM asymmetry at 2.8 σ at 10fb -1. If new physics is responsible for FB asymmetry, it will likely be heavy (m ≥ 500 GeV). 27

28. SM Higgs 28

29. SM Higgs 29

30. SM Higgs 30

31. SM Higgs 31

32. μ P T 32 GeV e P T 34 GeV ME T 47 GeV H → WW → llvv 32

33. H → ZZ → 4l 33

34. SM Higgs 34

35. MSSM Higgs Five massive Higgs bosons in the scalar sector: h, H, A, H +, H - Described by two parameters at the tree level: tan β and M A Search in ϕ → ττ channel. A large region in the MSSM parameter space is already excluded. 35

36. SUSY - Hadrons 36

37. SUSY - Leptons 37

38. SUSY - Limits Squark and gluino masses of ~ 1TeV can be excluded. 38

39. SUSY 39

40. SUSY Better LHC SUSY exclusion limits imply that SUSY particles will be less likely to be kinematically accessible at a 500 GeV LC. Fraction of undetected models with no sparticles kinematically accessible at LC as a function of LHC integrated luminosity. T. G. Rizzo, ALCPG11 40

41. Search for Narrow Dijet Resonances 41

42. Extra Dimensions in γγ 42

43. Microscopic Black Holes 43

44. 4 th Generation Quarks 44

45. B s → μμ 45

46. B Hadron Fraction 46

47. The LHC accelerator and CMS are working very well Measurements have shown that SM predictions for known physics have been essentially spot on There are no indications yet of new physics though the LHC experiments are now exploring new territory almost across the board. A long physics programme lies ahead as well as very exciting times. Summary 47

48. Back-up 48

49. Looking Further Ahead 60

50. Longer Term Planning 50

51. 59 Outlook -2012 Physics with > 1 thousand trillion proton-proton interactions Make more precise SM measurements – confront theory Search for the Higgs Boson Search for Supersymmetry Search for conjectured new physics Look and be prepared for the unexpected Prospects: SM Higgs Search (Mass in GeV) - from 2010 ATLAS + CMS each 95% CL 3  sensitivity5  sensitivity 5 fb -1 114 - 600 128 - 482 10 fb -1 114 - 600 117 - 535

52. Summary of CMS experimental results 52 First: Gauge bosons: Z, W, isolated-  First: Prompt J/  and B-hadrons through non-prompt J/  A First: Suppression of excited  Charged hadron multiplicity First: Jet imbalance and jet fragmentation function First dihadron correlations pp and PbPb in wide acceptance v 2 in wide acceptance First: h+- R AA p T up to100 GeV/c First: E T

53. Heavy Ion CMS experiment performed flawlessly during the 2010 heavy ion run period at LHC CMS has obtained significant statistics of hard probes CMS conducted detailed measurements of global properties of medium in PbPb and pp collisions Our measurements indicate consistent view of the hot and dense medium – Strong collective effects in the medium – No quenching of weakly and electromagnetically interacting probes – Strong quenching of partons, including b-quarks – Suppression of quarkonia, including excited states of the 